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Claire Snyder Lab
Researchers in the Claire Snyder Lab study the quality of cancer care, with a special focus on two areas: the quality of life for cancer patients undergoing treatment and the coordination of care between cancer specialists and primary care providers. As part of our quality-of-life research, we're investigating the use of patient-reported outcome questionnaires in routine oncology practice as well as developing a website for collecting the questionnaires and linking them with the electronic medical record. As part of our cancer-survivorship research, we've conducted large database studies to identify the physician specialties involved in the care of cancer survivors and to determine how that relates to survivors receiving recommended follow-up care. We're also working with investigators in the Sydney Kimmel Comprehensive Cancer Center to develop care strategies for breast cancer survivors.
Dmitri Artemov Lab
The Artemov lab is within the Division of Cancer Imaging Research in the Department of Radiology and Radiological Science. The lab focuses on 1) Use of advanced dynamic contrast enhanced-MRI and activated dual-contrast MRI to perform image-guided combination therapy of triple negative breast cancer and to assess therapeutic response. 2) Development of noninvasive MR markers of cell viability based on a dual-contrast technique that enables simultaneous tracking and monitoring of viability of transplanted stems cells in vivo. 3) Development of Tc-99m and Ga-68 angiogenic SPECT/PET tracers to image expression of VEGF receptors that are involved in tumor angiogenesis and can be important therapeutic targets. 4) Development of the concept of “click therapy” that combines advantages of multi-component targeting, bio-orthogonal conjugation and image guidance and preclinical validation in breast and prostate cancer models.
Research in the Ewald laboratory starts from a simple question: Which cells in a breast tumor are the most dangerous to the patient and most responsible for metastatic disease? To answer this question, we developed novel 3-D culture assays to allow real-time analysis of invasion. Our data reveal that K14+ cancer cells play a central role in metastatic disease and suggest that the development of clinical strategies targeting these cells will provide novel breast cancer treatments.
Our lab is focused on determining the role of hypoxia in breast cancer metastasis. We are particularly interested in the changes in the extracellular matrix that occur under hypoxic conditions and promote cancer cell migration.
The Institute for Computational Medicine's mission is to develop quantitative approaches for understanding the mechanisms, diagnosis and treatment of human disease through biological systems modeling, computational anatomy, and bioinformatics. Our disease focus areas include breast cancer, brain disease and heart disease.
The institute builds on groundbreaking research at both the Johns Hopkins University Whiting School of Engineering and the School of Medicine.
The Glunde lab is within the Division of Cancer Imaging Research in the Department of Radiology and Radiological Science. The lab is developing mass spectrometry imaging as part of multimodal molecular imaging workflows to image and elucidate hypoxia-driven signaling pathways in breast cancer. They are working to further unravel the molecular basis of the aberrant choline phospholipid metabolism in cancer. The Glunde lab is developing novel optical imaging agents for multi-scale molecular imaging of lysosomes in breast tumors and discovering structural changes in Collagen I matrices and their role in breast cancer and metastasis.
Radiopharmaceutical Therapy and Dosimetry Lab
The Radiopharmaceutical Therapy and Dosimetry (RTD) Lab has two missions: 1. Support clinical Radiopharmaceutical Therapy (RPT) trials by performing patient-specific dosimetry and developing novel methods that advance this field and illustrate the impact of a precision medicine approach to implementing treatment planning in RPT. This includes radiobiological modeling and microscale dosimetry calculations for alpha-particle emitter RPT. 2. Pre-clinical studies using novel alpha-emitter RPT agents with immune intact transgenic animal models that incorporate modeling and dosimetry to support the translation of novel targeted radionuclide therapy strategies to the clinic. In particular, identifying how to best combine RPT with complementary orthogonal-modality agents while also obtaining a basic understanding of how the treatment works and which variables have the greatest impact on efficacy and toxicity. The underlying objective is to utilize pre-clinical modeling and dosimetry to help id...entify an optimal therapeutic clinical trial design so as to reduce unnecessary human experimentation. view more